RU2552504C2 - Panel - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention refers to construction, in particular to a floor panel. A panel includes a body, mating locking devices located on opposite edges of the panel in the form of receiving and locking hooks. A receiving hook has a slot open to the upper side, and a locking hook has a slot open to the lower side and a projection entering the slot of the receiving hook. On the edge of the receiving hook a provision is made for a spring fastening tongue conjugated with a fastening cavity of the slot of the locking hook.

EFFECT: reduction of labour costs at locking of panels.

11 cl, 4 dwg

Description

The invention relates to a panel, in particular a panel for flooring, comprising a body with at least one polymer layer, counter-blocking means that are provided in pairs at the opposite edges of the panel so that several such panels are able to block with each other, at least one pair of locking means with hook-shaped profiles, namely, a receiving hook and an opposite locking hook, provided that the receiving hook has an edge of the hook located remotely from the body and located the receiving groove is narrow to the body, and the receiving groove is open to the upper side, that the locking hook is provided with a locking groove located close to the body and open to the lower side and having a locking protrusion located remotely from the body, which in the vertical direction of the joint enters the receiving groove of the receiving hook, that the locking hook has a connecting surface remote from the body and the vertically acting locking circuit remote from the body, that the receiving hook has a connecting surface close to the body and similarly close to the body a geometrical closure circuit that mates with a geometrical closure with the retaining loop of the locking hook remote from the body so as to enable vertical locking that the locking hook has a horizontal locking surface located close to the body on its locking protrusion, that the receiving hook has a remote location from the body horizontal locking surface in the receiving groove, which on the receiving hook is made narrowing the receiving hole through which the locking protrusion is made with the possibility of entering into the receiving groove essentially in the vertical direction of the docking.

A panel for flooring corresponding to the above is known from WO 2010/015516. The hook-shaped profiles of a known panel are tuned to the material from which the panel body is made. This allows you to engage such panels that have a body of soft bending and elastic polymer material. The locking contour, which is provided below the connecting surface of the locking hook, has areas that protrude relative to the plane of the connecting surface, and other areas that are backward relative to the plane of the connecting surface. In addition, the geometric circuit, which is provided below the connecting surface of the receiving hook, has areas that protrude relative to the plane of the connecting surface, and other areas that are backward relative to the plane of the connecting surface. The said protruding and backward regions of the geometrically closing contour and the retaining contour form undercuts that counteract the extension of both hook-shaped profiles in the direction perpendicular (vertically) to the panel plane. In order to be able to join undercuts in each other, the locking circuit and the geometric circuit are pressed against each other. Moreover, they must elastically deform. The locking circuit and the geometric circuit are soft elastic and can thus be brought into contact with each other with a geometric circuit. The maximum size of the undercut is limited due to the elastically soft properties of the polymer material. The vertical lock action is unsatisfactory.

The basis of the invention is the task of improving the panel in such a way as to increase the variety of polymeric materials that can be used for the body, and possibly improve the effect of vertical blocking.

In accordance with the invention, the problem is solved due to the fact that the locking contour of the locking hook remote from the body is spaced back from the plane of the connecting surface, and that the geometrical circuit close to the body of the receiving hook at least partially protrudes from the plane of the connecting surface of the receiving hook, which the locking protrusion and the receiving hole are made so that the end of the protrusion during the docking movement without elastic deformation of the hook-shaped profiles initially enters the receiving hole so that the horizon The total locking surface of the locking hook part of its surface is in contact with the horizontal locking surface of the receiving hook, and that the receiving hook has a bending bridge, which is designed in such a way that, by means of its elastic flexibility, can increase the width of the receiving hole, so that the locking protrusion is made with the possibility of full input into the receiving groove and, in addition, the locking loop of the locking hook is inserted into the geometric circuit of the receiving hook.

These measures allow the hook-like profiles to engage at the beginning of the docking movement without already becoming elastically deformed at this point of engagement. It is only during the further process of the joining movement that the undercut areas of the locking contour and the geometrical contour contour enter the contact point in such a way that elastic deformation is created, and a bending bridge is specially provided for elastic deformation. True, the retaining contour and the contour of the geometric circuit are also compressed and deformed, but the harder and more fragile the polymeric material of the body, the less significant the elastic deformation of the retainer circuit and the contour of the geometric circuit and the greater the proportion of elastic deformation of the bending bridge. By such an arrangement, it is now possible even if the body is made of relatively hard and brittle polymeric material, a high undercut size must be provided for geometric locking between the locking circuit and the geometric locking circuit. The geometrical closure circuit may, for example, have a locking element that protrudes further than in the prior art, and the locking circuit has a locking recess in response to the locking element, which is deeper than in the prior art. However, the locking circuit and the geometric circuit can be engaged without problems, since the bending bridge provided for this is elastically bent and this bending allows the receiving opening to expand. Thus, the locking loop and the loop circuit without strong self-deformation can move past each other until they are engaged.

The polymer layer of the body, respectively the core, can be made of a soft and elastic polymer material, such as a thermoplastic polymer, for example polyolefin, polypropylene, polyurethane or polyamide. As the soft polymeric material, the so-called soft polyvinyl chloride is also taken into account. In this case, we are talking about polyvinyl chloride, which contains a plasticizer. Fundamentally, however, polyvinyl chloride is an amorphous elastomer that has natural hardness and brittleness, which can only be reduced by means of a plasticizer.

However, it is preferable that the panel is made in such a way that it is also possible to make the polymer layer of the core from a polymer material with natural hardness and brittleness, for example from an amorphous elastomer, such as polyvinyl chloride, which does not contain at all or contains only a small amount of plasticizer.

Depending on the embodiment of the invention, the thickness of the panels according to the invention is 3-10 mm, preferably 4-8 mm, particularly preferably 5-6 mm. The density of the panels, depending on the thickness and specific composition, lies between 1-2.5 kg / m ² , preferably between 1.6-1.8 kg / m ² .

A spring-loaded locking tongue may be provided remotely from the body at the edge of the hook of the receiving hook, the locking groove close to the body having a locking recess that corresponds to a spring-loaded locking tongue. Thus, a second place is created inside the joint by hooks, which, by means of the elastic deformation provided and arranged for this area, namely the spring-loaded fixing tongue, can be joined. The spring-loaded locking tongue together with the locking groove also causes the blocking of both hook-shaped profiles in the vertical direction, that is, perpendicular to the plane of the blocked panels.

The elastic properties of the body can be used if the springy locking tab is made in one piece with the body. If the body is made of a relatively solid polymer material, this favors, inter alia, the manufacture of an spring-loaded fixing tongue by a cutting manufacturing method, such as, for example, by milling.

The spring-loaded locking tab is made on the side of the hook edge remote from the body, and the free end of the spring-loaded locking tab protrudes from the edge of the hook, for example, sloping downward. The spring-loaded locking tongue is always positioned so that contact with the reciprocal hook-shaped profile creates a deflection of the integral locking tongue, which moves the tongue closer to the body of its panel.

Advantageously, the spring retaining tab has a sliding surface remotely from the body. It comes into contact with the locking hook during a vertical docking movement. With this touch, the spring-loaded locking tab moves closer to the edge of the hook of the receiving hook. Thus, this tongue elastically strains and releases the docking path. The locking hook is then inserted further into the receiving hook until both panels are in the same plane.

Between the springy locking tongue and the edge of the hook, a free space may be provided in which the locking tongue can elastically bend. Elastic deformation allows the springy locking tab to spring back in the direction of its natural position, if there is space for this.

Advantageously, the locking recess has a locking contact surface. It, through contact with the springy fixing tab, helps to lock the connected panels in the vertical direction.

Advantageously, the locking contact surface is configured to form a restrictive bevel for the free end of the spring locking tongue. The restrictive bevel is designed so that the tensile locking tab, when it spring back in the direction of its natural position, hits / rests against this restrictive bevel. Further, it can be positioned so that the locking tongue abuts before it reaches its natural position, as a result of which the residual stress is constantly stored in the locking tongue, which serves to reliably lock.

A further advantage is obtained when the locking protrusion, on its side remote from the body, has an inclined surface called a sliding bevel as a sliding bevel. The sliding bevel is expediently designed so that it interacts with the region of the geometric circuit that protrudes. This region of the contour of the geometric circuit protruding from the docking plane forms, for example, a protruding locking element. The protruding region interacts with the sliding bevel of the locking protrusion. As soon as the sliding bevel comes in contact with the protruding region, for example, with the locking element, it slides along the locking element. As a result of this, at first, the mating surfaces of the receiving hook and the locking hook move apart. At the same time, the horizontal locking surface of the locking hook exerts a force that exerts pressure in the direction of the horizontal locking surface of the receiving hook. This force, introduced into the horizontal locking surface of the receiving hook, is transmitted to the bending bridge of the receiving hook, which consequently elastically bends. With further docking movement, the docking circuit passes the geometric circuit so that both reach the position in which they enter into each other with a geometric circuit. In this case, the bending stress in the bending bridge exerts a force on the horizontal locking surface of the receiving hook, which again strains the connecting surface of the locking hook in the direction of the connecting surface of the receiving hook. In this way, a closed joint can be achieved. In this case, the horizontal blocking surfaces of both hook-shaped profiles are pressed against each other.

Due to the geometric shape of the bevel (linear or curved), the degree of bending of the bending bridge can be affected. By varying the skew, the generated bending stress can be selected so that the polymer material in the area of the bending bridge is not overloaded and does not receive any damage.

A pair of response locking means is made in the form of rotary profiles. Namely, a groove profile with undercut of the groove wall and a ridge profile with undercut of the side of the ridge are provided.

This has the advantage that the panels can be suitably stacked so that the new panel is inserted (attached) into (k) the response (ohm) rotary (ohm) profile (s) of the panel already lying in the laying plane is installed and rotated downward.

In this case, it is preferable that at the same time the hook-shaped profile of the new panel can be locked with the hook-shaped profile of the panel in the same panel row. For this purpose, the locking hook of the new panel is lowered in a mite-like movement substantially in the vertical plane and inserted into the receiving hook. During said pincher-like motion, the locking protrusion first projects only at the end of the edge of the panel into the receiving opening. When advancing the movement similar to the movement of the ticks, the locking protrusion step by step enters the receiving opening. The elastic deformation of the bending bridge introduced as a result of this also increases step by step. When the panels, after all, are in the same plane, the locking circuit and the geometric circuit are precisely fitted , the mating surfaces touch and form a closed joint. In addition, the bending stress of the bending bridge is again eliminated, and the horizontal locking surfaces of both hook-shaped profiles are pressed against each other in a plane.

The scope can expand if a decorative layer is provided on the surface of the panel. Another benefit is due to the fact that a transparent protective layer is provided through which the decorative layer is visible. A transparent protective layer serves to protect the decorative layer. It may be provided with means that reduce wear, for example, corundum particles, glass particles, and the like. Moreover, it may be advantageous if a stabilizing layer is provided on the underside of the panel. This layer acts as a balance to the layers provided on the upper side to counteract the curvature of the panel.

Further, the invention is approximately illustrated in the drawings and is described in detail on the basis of several figures, which show:

FIG. 1a-1d - response blocking means of the first edge pair of the panel according to the invention, as well as stepwise docking movement to block two panels,

FIG. 2a-2d - an alternative implementation of the first edge pair of the response blocking means of the panel, as well as a step-by-step docking movement to block two panels,

FIG. 3 - flooring of the panels according to the invention, which have a second edge pair with counter blocking means, which are made in the form of rotary profiles,

FIG. 4 - an example of the implementation of the edge pair of rotary profiles.

FIG. 1a-1d respectively show partially two panels 1 and 2 respectively. Panels 1 and 2 are identical. Each separate panel has opposite profiles 3 and 4 respectively on the opposite edges of the panel of the edge pair. Therefore, for panel 1, the edge not shown is identical to profile 4 of panel 2, and for panel 2, the edge not shown is identical to profile 3 of panel 1.

For a panel with four edges, the second edge pair can be formed by mating profiles that are identical to the profiles of the first edge pair.

The sequence of FIG. 1a-1d shows in several steps the principal course of the docking movement for connecting and locking panels 1 and 2.

The response profiles 3 and 4 of each panel 1, respectively, 2 form the response blocking means V in the form of hook profiles N. The hook-shaped profile profile 1 forms a receiving hook 5, and the hook-shaped profile profile 2 forms a locking hook 6, which is included in the receiving hook 5, and both hook-shaped profiles are designed in such a way that locking is carried out. Locking counteracts the reversal of the docking movement. Thus, after the lock is completed, panels 1 and 2 cannot again separate from each other in the reverse movement.

Each panel 1, respectively 2, includes a body 1 ', respectively 2', with a polymer layer on which said counter blocking means V. are located. The upper side 7 of the panel forms a working surface.

On the receiving hook 5 there is provided a hook edge 8 remote from the body and a receiving groove 9 close to the body. The receiving groove 9 is open to the upper side 7.

The locking hook 6 is provided with a locking groove 11 located close to the body and open to the lower side 10 and has a locking protrusion 12 remote from the body. The locking protrusion in the vertical direction T of the docking is included in the receiving groove 9 of the receiving hook 5. Further, the locking hook 6 is remote from body connecting surface 13 and in the same way, the locking contour 14, acting with vertical locking, remote from the body, receiving hook 5 has a connecting surface close to the body and is also close to the body a geometrical closure circuit 16 that interlocks with the geometrical closure with the lock loop 14 of the lock hook 6. Thus, vertical locking is possible.

In addition, the locking hook 6 has a horizontal locking surface 17 located close to the body, which is located on its locking protrusion 12. Accordingly, for this, the receiving hook 5, located remotely from the body in the receiving groove 9, has a horizontal locking surface 18 that interacts with horizontal locking surface 17 of the locking hook 6.

The receiving hook 5 in its receiving groove 9 is provided with a narrowed receiving hole 19. The locking protrusion 12 is arranged to enter into the receiving groove 9 essentially in the vertical connecting direction T, that is, in a plane perpendicular to the plane of the blocked panels.

According to FIG. 1a-1d, the panel 1 with the receiving hook 5 is located on a rigid base (not shown). The locking protrusion 12 of the panel 2 is lowered perpendicular (vertically) to the plane of the panel. The locking contour 14 of the locking hook 5 remote from the body has a locking recess 14a that is spaced back from the plane of the connecting surface 13 of the locking hook 6. The geometrical closure circuit 16 close to the body at the receiving hook 5 is made so that it has a locking element 16a that protrudes the plane of the connecting surface 15 of the receiving hook 5 and in the locked state enters / captures the locking recess 14a of the locking hook 6. Otherwise, the locking protrusion 12 and the receiving hole 19 are made so that it is free to the end of the protrusion of the locking protrusion 12 at the beginning of the docking movement first without significant (noteworthy) elastic deformation of the hook profiles enters the receiving hole 19. In this case, the horizontal locking surface 17 of the locking hook 6 part of its surface comes into contact with the horizontal locking surface 18 of the receiving hook 5 .

A separate bending bridge (bridge) 20 is made on the receiving hook 5, which is best seen in FIG. 1b and 1s. The bending bridge 20 is designed in such a way that the width of the receiving hole 19 can be increased by means of its elastic flexibility, so that the locking protrusion 12 can be inserted into the receiving groove without problems 9. Furthermore, due to the flexibility of the bending bridge 20, the locking circuit 14 of the locking hook 6 can be very simple introduced into the circuit 16 of the geometric circuit of the receiving hook 5.

Hook-like profiles can be engaged at the beginning of the docking path without being elastically deformed at the engagement site. Only with further continuation of the connecting movement, the undercut areas of the retaining circuit 14 and the geometric circuit 16 come into contact at the meshing point. However, this contact causes elastic deformation, which occurs essentially in another place, namely in the bending bridge 20 provided for this. True, the locking circuit 14 and the geometric circuit 16 are also compressed and deformed, but the harder and brittle the polymeric material of the body, the smaller the elastic deformation of the locking circuit 14 and the contour 16 of the geometric circuit and the higher the proportion of elastic deformation of the bending bridge 20.

The locking recess 14a of the locking hook 6 is made deeper than in the prior art. Similarly, the fixing element 16a of the receiving hook 5 protrudes further from the connecting surface 15 of the receiving hook 5 than in the prior art. As a result of this, there is a greater amount of undercut in the vertical direction of the docking than in the prior art. Despite this, the locking circuit 14 and the geometric circuit 16 can be easily engaged. This is possible due to the fact that the bending bridge 20 is elastically flexible so that this bending allows the expansion of the receiving hole 19. Thus, the locking circuit 14 and the contour 16 of the geometric circuit can without strong deformation move past each other as long as they will not be engaged with a geometric closure and their vertical blocking action will not be manifested.

In FIG. 1b, it is shown that, on the locking protrusion 12, one inclined surface is provided remotely from the body, which forms a sliding bevel 12a. The sliding bevel touches the protruding locking element 16A of the contour 16 of the geometric closure of the receiving hook. As a result of this, a horizontal movement is superimposed during the vertical docking movement of the locking hook 6, which extends the panels one from another, so that a gap is formed between the docking surfaces 13, 15. At the same time, the horizontal locking surface 17 of the locking hook 6 exerts a force that exerts pressure on the horizontal locking surface 18 of the receiving hook 5. The force that acts on the horizontal locking surface 18 of the receiving hook 5 is transmitted to the bending bridge 20 of the receiving hook 5, which therefore resiliently bends.

With further docking movement according to FIG. 1c, the widest portion of the locking protrusion passes through the widened receiving hole 19 of the receiving groove 9. Then, the bending of the bending bridge 20 is reduced and the receiving hole 19 is again narrowed. The connecting surfaces 13, 15 of the panels located at a distance k are compressed by each other by means of the bending stress of the bending bridge 20.

In FIG. 1d, the locking circuit 14 and the geometric circuit 16 have reached the position in which they entered the geometric circuit with each other. The hook-shaped profiles H can be designed so that the remainder of the bending stress of the bending bridge 20 is maintained and exerts an elastic force (spring force) through the horizontal locking surface 18 of the receiving hook 5, which exerts a constant voltage on the connecting surface 13 of the locking hook 6 in the direction of the connecting surface 15 of the receiving hook 5. Thus, a long-term closed joint can be achieved. In FIG. 1d, the horizontal locking surfaces 17, 18 of both hook profiles H are pressed against each other and do not exert any constant voltage.

FIG. 2a-2d show, respectively, individual fragments of the two panels 1 and 2. These panels are again identical. Each individual panel has the opposite profiles on the opposite edges of the panel of the edge pair. For a panel with four edges, a second edge pair can be made with mating profiles that are identical to the edges of the panel of the first edge pair.

The sequence of figures again explains at several stages 2a-2d the principal flow of the docking movement for connecting and locking the panels.

An exemplary embodiment of the panel 1, respectively 2, according to FIG. 2a-2d significantly corresponds to the embodiment of FIG. 1a-1d. In this regard, the same reference numbers are used for identical features, as in FIG. 1a-1d. According to FIG. 2a-2d, a second geometric locking is provided. For this purpose, a spring-loaded locking tongue is provided, which is made on the edge 8 of the receiving hook 5. The locking groove 11 has a locking recess 11 close to the body, which is aligned with the spring-loaded locking tongue 21. Thus, a second place is created inside the hooks by elastic deformation provided and arranged for this area, namely the springy locking tab 21, can be docked without problems. In the same way, the springy locking tab 21 together with the locking groove 9 helps to lock both hook-shaped profiles H in the vertical direction, i.e. perpendicular to the plane of the blocked panels.

The spring-loaded locking tab 21 is made in one piece with the body. In this regard, the elastic properties of the body are used. For the blocking effect of the springy locking tab 21, it is advantageous if the polymeric material of the body is relatively hard and flexural. Therefore, a harder polymer material is better than a soft polymer material that is easily malleable.

The spring-loaded locking tab 21 projects obliquely downward from the edge 8 of the hook. When the panel 1 with its lower side 10 lies on the base (not shown), the free end of the springy locking tab 21 points in the direction of the base. The spring-loaded locking tongue 21 has a sliding surface 23 remote from the body, which, during the docking movement, comes into contact with the locking hook 6 and thus creates a deflection of the spring-loaded locking tongue 21. By deflection, the locking tongue 21 is moved closer to the edge 8 of the hook, respectively closer to the body panels 1. In this case, the spring-loaded locking tab 21 elastically strains and releases the vertical connecting path so that the locking hook 6 can lower further. Then, the locking hook 6 can be inserted further into the receiving hook 5 until both panels 1 and 2 are in the same plane. Between the springy locking tab 21 and the edge of the hook 8 there is a free space 24 into which the locking tab 21 can elastically bend. The elastic tension of the locking tab 21 allows the locking tab to spring in the direction of its neutral position, if space is provided for this. Place is provided when the locking tongue 21 during the docking movement enters the region of the locking recess 22 of the locking hook 6. The locking recess 22 has a locking contact surface 25 which, by contact with the spring locking tongue 21, causes vertical locking of the connected panels, i.e. perpendicular to the plane of the panels .

The locking contact surface 25 is made in such a way that it forms a restrictive bevel for the free end of the spring-loaded fixing tongue 21. The restrictive bevel 26 is made in such a way that the strained spring locking tongue 21, when it is spring-loaded in the direction of its neutral position, moves relative to this limiting bevel 26 until it reaches its neutral position. So, the remainder of the initial stress is always stored in the locking tongue 21, as a result of which a reliable locking is provided.

A preferred embodiment of the quadrangular panel is seen in FIG. 3, which shows a fragment of the manufacture of flooring from the panels of the invention. In the case of the panels used, we are talking about an embodiment with a first edge pair that has reciprocal hook-shaped profiles H, and also with a second edge pair that is equipped with reciprocal geometrically lockable swivel profiles S. The swivel profiles S are used to connect panels of different panel rows to each other . In this embodiment, the hook-shaped profiles H serve to connect with each other the profiles of the same panel rows. The hook profiles H of the first edge pair can be made as in the embodiment of FIG. 1a-1d. Alternatively, the hook profiles H of the first edge pair may correspond to the embodiment of FIG. 2a-2d.

FIG. 3 shows in the very first panel row III a new panel 27, which should be locked both with the previous panel row II, and with the neighboring panel 28 of the same panel row III. The new panel 27 is installed at an angle to the plane of the laid panels and is attached with its rotary profile S to the previous panel row II. Then it is blocked by turning the stacked panels into the plane with the previous panel row II. At the same time, the hook-shaped profile (locking hook 6) of the new panel 27 with the hook-shaped profile (receiving hook 5) of the panel 28 of the same panel row III is also blocked. The locking hook 6, when the new panel 27 is pivotally lowered into the plane of the stacked panels, at the same time as in the movement of the ticks, the docking movement engages with the receiving hook 5. The receiving hook 5 has a bending bridge, the elastic bending of which is carried out step by step, the further the locking hook 6 moves in the direction of the receiving hook 5, respectively, the further the locking protrusion of the locking hook 6 is inserted into the receiving groove of the receiving hook 5.

For the second edge pair, all known geometrically closable profiles that can be connected with a geometric closure by tilting the new panel to the previous panel row and then turning the new panel down into the plane of the laid panels are taken into account as response rotary profiles S. An embodiment for such a rotary profile S is shown in FIG. four.

The counter rotary profiles S according to FIG. 4 include a groove (tongue and groove) profile 29 and a ridge profile 30. The groove profile 29 has an upper groove wall 29a that is shorter than the lower groove wall 29b. The bottom wall 29b of the groove is further provided with an undercut recess 29c for the ridge profile. In addition, the recess 29c has a horizontal blocking surface 29d. The ridge profile 30 is provided with an upper side 30a of the ridge, which is substantially parallel to the upper side 7 of the new panel 27. The lower side 30b of the ridge has an undercut 30c and a horizontal blocking surface 30d that interacts with the horizontal blocking surface 29d of the bottom groove wall 29b. The tilted position of the new panel 27 according to FIG. 3 in FIG. 4 is indicated by the dotted position of the ridge profile 30 '. The lower side 30b of the ridge is superimposed on the longer lower groove wall 29b. The new panel 27 is pushed forward by the end of the ridge into the groove profile, and then this new panel 27 is pivotally lowered into the plane of the stacked panels.

LIST OF REFERENCE POSITIONS

1 panel

1 'body

2 panel

2 'body

3 profile

4 profile

5 receiving hook

6 locking hook

7 top side

8 hook edge

9 receiving groove

10 bottom side

11 locking groove

12 locking tab

12a sliding bevel

13 docking surface (locking hook)

14 locking circuit

14a locking recess

15 docking surface (receiving hook)

16 geometric circuit

16a locking element

17 horizontal locking surface (locking hook)

18 horizontal locking surface (receiving hook)

19 inlet

20 bending bridge

21 spring-loaded locking tab

22 fixing recess

23 sliding surface

24 free space

25 locking contact surface

26 limit bevel

27 new panel

27 'new panel

28 panel

29 groove profile

29a upper wall of the groove

29b bottom wall of the groove

29c undercut recess

29d horizontal blocking surface

30 ridge profile

30a spring upper side

30b spring bottom

30s undercut

30d horizontal blocking surface

30 'ridge profile

H hook profile

k distance

S swivel profile

T Docking Direction

V response blocking means

Claims (11)

1. The panel (1, 2, 27, 28), including the body (1 ', 2') with at least one polymer layer, the response blocking means (V), which are provided in pairs at the opposite edges of the panel, at least one pair of locking means with hook-shaped profiles (H), namely a receiving hook (5) and an opposing locking hook (6), provided that the receiving hook (5) has a hook edge (8) located remotely from the body and a receiving groove (9) located close to the body, wherein the receiving groove (9) is open to the upper side (7), that the locking hook (6) is provided with a laid close to the body and open to the lower side of the locking groove (11) and has a locking protrusion (12) located remotely from the body, which in the vertical direction of the joint enters the receiving groove (9) of the receiving hook (5) that the locking hook (6) has a mating surface remote from the body (13) and a vertically acting locking circuit (14) that is equally remote from the body, that the receiving hook (5) has a mating surface (15) close to the body and a circuit (16) that is also close to the body a geometric closure that mates with a geometric vice by touching the locking loop (14) of the locking hook (6) remote from the body so as to enable vertical locking that the locking hook (6) has a horizontal locking surface (17) located close to the body on its locking lug (12), which the receiving hook (5) has a horizontal locking surface (18) located remote from the body in the receiving groove (9), which has a tapering receiving hole (19) on the receiving hook (5), through which the locking protrusion (12) can be inserted into the receiving groove (9) essentially in vertical n in the direction (T) of the docking that the free end of the locking protrusion (12) is made narrower than the width of the receiving hole (19) of the receiving hook (5), characterized in that the locking contour (14) of the locking hook (6) remote from the body is spaced back from the plane of the connecting surface (13) of the locking hook (6), which is close to the body contour (16) of the geometric circuit at the receiving hook (5) at least partially protrudes beyond the plane of the connecting surface (15) of the receiving hook (5), that the locking protrusion (12) and the inlet (19) are made so that the end protrudes pa during the docking movement without elastic deformation of the hook-shaped profiles (H) initially so enters the receiving hole (19) that the horizontal locking surface (17) of the locking hook (6) receives part of its surface in contact with the horizontal locking surface (18) of the receiving hook ( 5), and that the receiving hook (5) has a bending bridge (20), which is made so that due to its elastic compliance, the width of the receiving hole (19) can increase, so that the locking protrusion (12) is made with the possibility of full input into the receiving the groove (9) and, in addition, the locking circuit (14) of the locking hook (6) is inserted into the geometric circuit (16) of the receiving hook (5), and a springy spring is provided remotely from the body at the edge (8) of the receiving hook (5) a locking tongue (21), and that the locking groove (11) is close to the body has a locking recess (22) that mates with a spring-loaded locking tongue (21). 2. The panel according to claim 1, characterized in that the spring-loaded fixing tab (21) is made in one piece with the body (1 '). 3. The panel according to claim 1 or 2, characterized in that the spring-loaded locking tab (21) is made on the side of the edge (8) of the hook remote from the body and that the free end of the spring-loaded locking tab (21) slopes outward from the edge (8) of the hook. 4. The panel according to claim 1, characterized in that the spring-loaded fixing tab (21) remotely from the body has a sliding surface (23). 5. The panel according to claim 1, characterized in that a free space (24) is provided between the spring fixing tongue (21) and the hook edge (8), into which the locking tongue (21) can elastically bend. 6. The panel according to claim 1, characterized in that the fixing recess (22) has a locking contact surface (25). 7. The panel according to claim 6, characterized in that the locking contact surface (25) is made so that it forms a limiting bevel (26) for the free end of the spring-loaded locking tongue (21). 8. The panel according to claim 1, characterized in that the locking protrusion (12) has a sliding bevel (12a) on its side remote from the body. 9. The panel according to claim 1, characterized in that a pair of rotary profiles (S) is provided, namely a groove profile (29) with undercut of the wall (29b) of the groove and a ridge profile (30) with undercut (30c) of the ridge side (30b) . 10. The panel according to claim 1, characterized in that a transparent covering protective layer is provided for on the upper side (7) and that a decorative layer visible through the protective layer is provided. 11. The panel according to claim 1, characterized in that a stabilizing layer is provided on its lower side.

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